blob: 574d2f147ad90d626ce86cc5d1b15107201e8d5f [file] [log] [blame]
// Copyright 2013 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include <stddef.h>
#include <stdint.h>
#include "base/lazy_instance.h"
#include "base/location.h"
#include "base/threading/thread_task_runner_handle.h"
#include "base/time/time.h"
#include "cc/debug/lap_timer.h"
#include "cc/raster/raster_buffer.h"
#include "cc/test/begin_frame_args_test.h"
#include "cc/test/fake_impl_task_runner_provider.h"
#include "cc/test/fake_layer_tree_host_impl.h"
#include "cc/test/fake_output_surface.h"
#include "cc/test/fake_output_surface_client.h"
#include "cc/test/fake_picture_layer_impl.h"
#include "cc/test/fake_raster_source.h"
#include "cc/test/fake_tile_manager.h"
#include "cc/test/fake_tile_manager_client.h"
#include "cc/test/fake_tile_task_manager.h"
#include "cc/test/test_layer_tree_host_base.h"
#include "cc/test/test_shared_bitmap_manager.h"
#include "cc/test/test_task_graph_runner.h"
#include "cc/test/test_tile_priorities.h"
#include "cc/tiles/tile.h"
#include "cc/tiles/tile_priority.h"
#include "cc/trees/layer_tree_impl.h"
#include "testing/gtest/include/gtest/gtest.h"
#include "testing/perf/perf_test.h"
namespace cc {
namespace {
static const int kTimeLimitMillis = 2000;
static const int kWarmupRuns = 5;
static const int kTimeCheckInterval = 10;
base::LazyInstance<FakeTileTaskManagerImpl> g_fake_tile_task_manager =
LAZY_INSTANCE_INITIALIZER;
class TileManagerPerfTest : public TestLayerTreeHostBase {
public:
TileManagerPerfTest()
: timer_(kWarmupRuns,
base::TimeDelta::FromMilliseconds(kTimeLimitMillis),
kTimeCheckInterval) {}
void InitializeRenderer() override {
host_impl()->SetVisible(true);
host_impl()->InitializeRenderer(output_surface());
tile_manager()->SetTileTaskManagerForTesting(
g_fake_tile_task_manager.Pointer());
}
void SetupDefaultTreesWithFixedTileSize(const gfx::Size& layer_bounds,
const gfx::Size& tile_size) {
scoped_refptr<FakeRasterSource> pending_raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
scoped_refptr<FakeRasterSource> active_raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
SetupPendingTree(std::move(active_raster_source), tile_size, Region());
ActivateTree();
SetupPendingTree(std::move(pending_raster_source), tile_size, Region());
}
void RunRasterQueueConstructTest(const std::string& test_name,
int layer_count) {
TreePriority priorities[] = {SAME_PRIORITY_FOR_BOTH_TREES,
SMOOTHNESS_TAKES_PRIORITY,
NEW_CONTENT_TAKES_PRIORITY};
int priority_count = 0;
std::vector<FakePictureLayerImpl*> layers = CreateLayers(layer_count, 10);
for (const auto& layer : layers)
layer->UpdateTiles();
timer_.Reset();
do {
std::unique_ptr<RasterTilePriorityQueue> queue(
host_impl()->BuildRasterQueue(priorities[priority_count],
RasterTilePriorityQueue::Type::ALL));
priority_count = (priority_count + 1) % arraysize(priorities);
timer_.NextLap();
} while (!timer_.HasTimeLimitExpired());
perf_test::PrintResult("tile_manager_raster_tile_queue_construct",
"",
test_name,
timer_.LapsPerSecond(),
"runs/s",
true);
}
void RunRasterQueueConstructAndIterateTest(const std::string& test_name,
int layer_count,
int tile_count) {
TreePriority priorities[] = {SAME_PRIORITY_FOR_BOTH_TREES,
SMOOTHNESS_TAKES_PRIORITY,
NEW_CONTENT_TAKES_PRIORITY};
std::vector<FakePictureLayerImpl*> layers = CreateLayers(layer_count, 100);
for (const auto& layer : layers)
layer->UpdateTiles();
int priority_count = 0;
timer_.Reset();
do {
int count = tile_count;
std::unique_ptr<RasterTilePriorityQueue> queue(
host_impl()->BuildRasterQueue(priorities[priority_count],
RasterTilePriorityQueue::Type::ALL));
while (count--) {
ASSERT_FALSE(queue->IsEmpty());
ASSERT_TRUE(queue->Top().tile());
queue->Pop();
}
priority_count = (priority_count + 1) % arraysize(priorities);
timer_.NextLap();
} while (!timer_.HasTimeLimitExpired());
perf_test::PrintResult(
"tile_manager_raster_tile_queue_construct_and_iterate",
"",
test_name,
timer_.LapsPerSecond(),
"runs/s",
true);
}
void RunEvictionQueueConstructTest(const std::string& test_name,
int layer_count) {
TreePriority priorities[] = {SAME_PRIORITY_FOR_BOTH_TREES,
SMOOTHNESS_TAKES_PRIORITY,
NEW_CONTENT_TAKES_PRIORITY};
int priority_count = 0;
std::vector<FakePictureLayerImpl*> layers = CreateLayers(layer_count, 10);
for (const auto& layer : layers) {
layer->UpdateTiles();
for (size_t i = 0; i < layer->num_tilings(); ++i) {
tile_manager()->InitializeTilesWithResourcesForTesting(
layer->tilings()->tiling_at(i)->AllTilesForTesting());
}
}
timer_.Reset();
do {
std::unique_ptr<EvictionTilePriorityQueue> queue(
host_impl()->BuildEvictionQueue(priorities[priority_count]));
priority_count = (priority_count + 1) % arraysize(priorities);
timer_.NextLap();
} while (!timer_.HasTimeLimitExpired());
perf_test::PrintResult("tile_manager_eviction_tile_queue_construct",
"",
test_name,
timer_.LapsPerSecond(),
"runs/s",
true);
}
void RunEvictionQueueConstructAndIterateTest(const std::string& test_name,
int layer_count,
int tile_count) {
TreePriority priorities[] = {SAME_PRIORITY_FOR_BOTH_TREES,
SMOOTHNESS_TAKES_PRIORITY,
NEW_CONTENT_TAKES_PRIORITY};
int priority_count = 0;
std::vector<FakePictureLayerImpl*> layers =
CreateLayers(layer_count, tile_count);
for (const auto& layer : layers) {
layer->UpdateTiles();
for (size_t i = 0; i < layer->num_tilings(); ++i) {
tile_manager()->InitializeTilesWithResourcesForTesting(
layer->tilings()->tiling_at(i)->AllTilesForTesting());
}
}
timer_.Reset();
do {
int count = tile_count;
std::unique_ptr<EvictionTilePriorityQueue> queue(
host_impl()->BuildEvictionQueue(priorities[priority_count]));
while (count--) {
ASSERT_FALSE(queue->IsEmpty());
ASSERT_TRUE(queue->Top().tile());
queue->Pop();
}
priority_count = (priority_count + 1) % arraysize(priorities);
timer_.NextLap();
} while (!timer_.HasTimeLimitExpired());
perf_test::PrintResult(
"tile_manager_eviction_tile_queue_construct_and_iterate",
"",
test_name,
timer_.LapsPerSecond(),
"runs/s",
true);
}
std::vector<FakePictureLayerImpl*> CreateLayers(int layer_count,
int num_tiles_in_high_res) {
// Compute the width/height required for high res to get
// num_tiles_in_high_res tiles.
float width = std::sqrt(static_cast<float>(num_tiles_in_high_res));
float height = num_tiles_in_high_res / width;
// Adjust the width and height to account for the fact that tiles
// are bigger than 1x1.
LayerTreeSettings settings;
width *= settings.default_tile_size.width();
height *= settings.default_tile_size.height();
// Ensure that we start with blank trees and no tiles.
host_impl()->ResetTreesForTesting();
tile_manager()->FreeResourcesAndCleanUpReleasedTilesForTesting();
gfx::Size layer_bounds(width, height);
gfx::Size viewport(width / 5, height / 5);
host_impl()->SetViewportSize(viewport);
SetupDefaultTreesWithFixedTileSize(layer_bounds,
settings.default_tile_size);
std::vector<FakePictureLayerImpl*> layers;
// Pending layer counts as one layer.
layers.push_back(pending_layer());
int next_id = layer_id() + 1;
// Create the rest of the layers as children of the root layer.
scoped_refptr<FakeRasterSource> raster_source =
FakeRasterSource::CreateFilled(layer_bounds);
while (static_cast<int>(layers.size()) < layer_count) {
std::unique_ptr<FakePictureLayerImpl> child_layer =
FakePictureLayerImpl::CreateWithRasterSource(
host_impl()->pending_tree(), next_id, raster_source);
child_layer->SetBounds(layer_bounds);
child_layer->SetDrawsContent(true);
layers.push_back(child_layer.get());
pending_layer()->test_properties()->AddChild(std::move(child_layer));
++next_id;
}
// Property trees need to be rebuilt because layers were added above.
host_impl()->pending_tree()->property_trees()->needs_rebuild = true;
host_impl()->pending_tree()->BuildLayerListAndPropertyTreesForTesting();
bool update_lcd_text = false;
host_impl()->pending_tree()->UpdateDrawProperties(update_lcd_text);
for (FakePictureLayerImpl* layer : layers)
layer->CreateAllTiles();
return layers;
}
GlobalStateThatImpactsTilePriority GlobalStateForTest() {
GlobalStateThatImpactsTilePriority state;
gfx::Size tile_size = LayerTreeSettings().default_tile_size;
state.soft_memory_limit_in_bytes =
10000u * 4u *
static_cast<size_t>(tile_size.width() * tile_size.height());
state.hard_memory_limit_in_bytes = state.soft_memory_limit_in_bytes;
state.num_resources_limit = 10000;
state.memory_limit_policy = ALLOW_ANYTHING;
state.tree_priority = SMOOTHNESS_TAKES_PRIORITY;
return state;
}
void RunPrepareTilesTest(const std::string& test_name,
int layer_count,
int approximate_tile_count_per_layer) {
std::vector<FakePictureLayerImpl*> layers =
CreateLayers(layer_count, approximate_tile_count_per_layer);
timer_.Reset();
do {
host_impl()->AdvanceToNextFrame(base::TimeDelta::FromMilliseconds(1));
for (const auto& layer : layers)
layer->UpdateTiles();
GlobalStateThatImpactsTilePriority global_state(GlobalStateForTest());
tile_manager()->PrepareTiles(global_state);
tile_manager()->Flush();
timer_.NextLap();
} while (!timer_.HasTimeLimitExpired());
perf_test::PrintResult("prepare_tiles", "", test_name,
timer_.LapsPerSecond(), "runs/s", true);
}
TileManager* tile_manager() { return host_impl()->tile_manager(); }
protected:
LapTimer timer_;
};
TEST_F(TileManagerPerfTest, PrepareTiles) {
RunPrepareTilesTest("2_100", 2, 100);
RunPrepareTilesTest("2_500", 2, 500);
RunPrepareTilesTest("2_1000", 2, 1000);
RunPrepareTilesTest("10_100", 10, 100);
RunPrepareTilesTest("10_500", 10, 500);
RunPrepareTilesTest("10_1000", 10, 1000);
RunPrepareTilesTest("50_100", 100, 100);
RunPrepareTilesTest("50_500", 100, 500);
RunPrepareTilesTest("50_1000", 100, 1000);
}
TEST_F(TileManagerPerfTest, RasterTileQueueConstruct) {
RunRasterQueueConstructTest("2", 2);
RunRasterQueueConstructTest("10", 10);
RunRasterQueueConstructTest("50", 50);
}
TEST_F(TileManagerPerfTest, RasterTileQueueConstructAndIterate) {
RunRasterQueueConstructAndIterateTest("2_16", 2, 16);
RunRasterQueueConstructAndIterateTest("2_32", 2, 32);
RunRasterQueueConstructAndIterateTest("2_64", 2, 64);
RunRasterQueueConstructAndIterateTest("2_128", 2, 128);
RunRasterQueueConstructAndIterateTest("10_16", 10, 16);
RunRasterQueueConstructAndIterateTest("10_32", 10, 32);
RunRasterQueueConstructAndIterateTest("10_64", 10, 64);
RunRasterQueueConstructAndIterateTest("10_128", 10, 128);
RunRasterQueueConstructAndIterateTest("50_16", 50, 16);
RunRasterQueueConstructAndIterateTest("50_32", 50, 32);
RunRasterQueueConstructAndIterateTest("50_64", 50, 64);
RunRasterQueueConstructAndIterateTest("50_128", 50, 128);
}
TEST_F(TileManagerPerfTest, EvictionTileQueueConstruct) {
RunEvictionQueueConstructTest("2", 2);
RunEvictionQueueConstructTest("10", 10);
RunEvictionQueueConstructTest("50", 50);
}
TEST_F(TileManagerPerfTest, EvictionTileQueueConstructAndIterate) {
RunEvictionQueueConstructAndIterateTest("2_16", 2, 16);
RunEvictionQueueConstructAndIterateTest("2_32", 2, 32);
RunEvictionQueueConstructAndIterateTest("2_64", 2, 64);
RunEvictionQueueConstructAndIterateTest("2_128", 2, 128);
RunEvictionQueueConstructAndIterateTest("10_16", 10, 16);
RunEvictionQueueConstructAndIterateTest("10_32", 10, 32);
RunEvictionQueueConstructAndIterateTest("10_64", 10, 64);
RunEvictionQueueConstructAndIterateTest("10_128", 10, 128);
RunEvictionQueueConstructAndIterateTest("50_16", 50, 16);
RunEvictionQueueConstructAndIterateTest("50_32", 50, 32);
RunEvictionQueueConstructAndIterateTest("50_64", 50, 64);
RunEvictionQueueConstructAndIterateTest("50_128", 50, 128);
}
} // namespace
} // namespace cc